JPH1198182A - Acknowledge trace for edi transaction in internet and automatic facsimile transmission system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To attain reliable data transfer by monitoring an acknowledge signal and automatically transmitting data at the time of determining that a 2nd computer system does not receive data. SOLUTION: A computer 110 is connected to a computer 120 through the Internet 130. In the constitution, data are transferred between the computers 110, 120 through the Internet 130. When the computer 120 receives data stored in the computer 110 through the Internet 130, the computer 120 sends a receiving aknowledge signal to the computer 110, which monitors the received signal. When the reception of data are not acknowledged within prescribed time, data are automatically transmitted through a facsimile. Consequently a method for executing reliable data transfer on a global computer network can be obtained.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

FIELD OF THE INVENTION The present invention relates generally to EDI transactions and, more particularly, to a method for performing EDI transactions over the Internet.

[0002]

2. Description of the Related Art Data transfer between business partners is as follows.
It is commonly used by companies that provide related services to allow automatic or semi-automatic sharing of information. For example,
If a manufacturer outsources repair and service orders to a personal service provider, data describing the service order ordered by the client to the manufacturer needs to be sent to the personal service provider. Further, data evaluating a manufacturer for service call progress must be resent to the manufacturer by an individual service provider to keep accurate records with the manufacturer.

[0003]

Current systems for transferring data related to service orders between business partners perform the data transfer over a direct connection between the business partners or via a third party communication partner. However, maintaining a direct connection between business partners is expensive because a dedicated line is maintained between the partners. Often the data transfer capacity between business partners is not sufficient to reimburse the cost of maintaining a dedicated line. In order to reduce costs, the data transfer is therefore performed via a third party communication partner. Third party communication partners make data transfer more economical by providing the same service to a very large number of clients. However, third party communication partners typically perform data transfer batch-over-night. As a result, a typical turnaround time for providing a call service via a personal service provider requires several working days. This is undesirable in environments that require a quick response to service calls. Accordingly, a need exists for an inexpensive method and apparatus for transferring data between business partners that allows for a fast turnaround time for service calls.

[0004] It is an object of the present invention to provide a method and apparatus for performing a reliable data transfer operation in a global computer network.

[0005]

SUMMARY OF THE INVENTION An object of the present invention is to provide a method for performing reliable data transfer on a global computer network, the method comprising storing the data in a first computer system connected to the global computer network. Transmitting the data to a second computer system connected to the global computer network; receiving the data from the second computer system to the first computer system;
Sending an acknowledgment signal to the second computer system; monitoring the acknowledgment signal received by the first computer system to determine whether the data has been received by the second computer system; The method is accomplished by automatically transmitting data via facsimile upon a determination that the data was not received by the computer system.

[0006] The method of the present invention may further comprise the step of automatically transmitting a paging signal upon determining that no data has been received by the second computer system. In the method of the present invention, the data reception may be acknowledged in real time. The object of the present invention is also a computer system for performing reliable data transfer on a global computer network, the system comprising a first and a second programmed computer connected to the global computer network. A first computer that transmits data stored on a first computer system connected to the global computer network to a second computer system connected to the global computer network; the data is transmitted by the second computer system. Monitoring the acknowledgment signal received by the first computer system to determine if it was received; and facsimile by determining that no data was received by the second computer system. It is achieved by a computer system comprising an instruction for transmitting the data automatically through.

In the computer system of the present invention, the second
Receiving the data from the second computer system to the first computer system by receiving the data on the second computer system connected to the global computer network; and receiving the data on the second computer system. You may comprise so that the command which sends a response signal may be further provided. In the computer system of the present invention, the first programmed computer system further comprises instructions for automatically transmitting a paging signal upon a determination that no data was received by the second computer system. You may comprise. Further, the above object of the present invention is a computer readable medium storing a computer program, the program connecting data stored in a first computer system connected to the global computer network to the global computer network. Monitoring the acknowledgment signal received by the first computer system to determine whether data has been received by the second computer system; and transmitting the data to the second computer system. This is accomplished by a computer readable medium having instructions to automatically transmit data via facsimile upon a determination that it has not been received by the computer system.

[0008] The computer readable medium of the present invention may further comprise instructions for automatically transmitting a paging signal upon a determination that the data was not received by the second computer system. . The present invention also relates to a computer-readable medium storing a computer program, the program receiving data at a second computer system connected to a global computer network; and the second computer system. This is achieved by a computer-readable medium comprising instructions for receiving and sending an acknowledgment signal from a second computer system to a first computer system by receiving data.

[0009]

According to an embodiment of the present invention, there is provided a method and apparatus for performing a reliable data transfer operation in a global computer network. This involves transmitting data stored on a first computer system connected to the global computer network to a second computer system connected to the global computer network, and transmitting the data when the data is received at the second computer system. Receiving the acknowledgment signal in the first computer system, monitoring the acknowledgment signal received in the first computer system, and automatically transmitting the data via facsimile if the data reception is not acknowledged within a predetermined time. Achieved by sending. In addition, a paging signal is automatically sent to the business partner to indicate that the data has been transferred by facsimile.

[0010] Unlike the prior art, where data transfer is performed batch-offline, embodiments of the present invention allow data transfer operations to be performed online in real time. Furthermore, utilizing a global computer network eliminates the need to maintain dedicated communication lines between the first and second computer systems, and allows the first and second computer systems to communicate with a significant number of computer systems connected to the global computer network. A single computer system can be used with two computer systems.

[0011]

DESCRIPTION OF THE PREFERRED EMBODIMENTS A method and apparatus according to embodiments of the present invention perform data transfer operations between computer systems connected to a global computer network, such as the Internet. 1A-1B show a configuration of a data transfer system according to an embodiment of the present invention. In FIG. 1A, computer 110 is connected to computer 120 via global network 130. Data is transferred between the computer 110 and the computer 120 via the global network 130. Computer 110
And computer 120 may be any general purpose or special purpose computer known in the art. For example, in one embodiment, computer 110 and computer 120 are personal computers executing a wide variety of software applications, and in other embodiments, computer 110 and computer 120 are dedicated workstations. Global Network 13
0 is any of the global networks known in the art. For example, in a preferred embodiment of the present invention, global network 130 is the Internet. The Internet is “ComputerNetworks: Third Edition”, by reference, incorporated herein by reference in its entirety.
Andrew S. Tanenbaum (Upper Saddle River, NJ: Pren
tice-Hall, 1996).

FIG. 1B illustrates computers 110 and 120.
1 shows a configuration of the data transfer module 100. Computers 110 and 120 have a call management system 105. Call management system 105 may be any suitable system known in the art for managing service orders. While call management system 105 is described herein as part of computers 110 and 120, call management system 105 may also be part of a separate computer system in communication with computer 110 or 120. Further, computers 110 and 120 may use different call management systems 105. In particular, call management system 105 of computers 110 and 120 may use different data formats to represent service orders.

The data transfer module 100 of the computer 110 or 120
Converts the data retrieved from the call management system 105, encrypts the data extracted from the database to ensure secure data transfer, and sends the encrypted data to another computer 110 or 120. Data transfer module 1 of receiving computer 110 or 120
00 then decrypts the data received over the global network 130 and sends the decrypted data to the call management system 1 of the receiving computer 110 or 120.
Convert to a format compatible with X.05. As will be described more fully below, the receiving computer 110 or 120 can then
Send an acknowledgment signal back to the sending computer 110 or 120.

The data transfer module 1 shown in FIG. 1B
00 uses an extraction module 115, an outbound conversion module 125, and an encryption module 135 to handle output data transfer. Further, the data transfer module 100 uses a decryption module 145, an inbound conversion module 155, and a merge module 165 to handle input data transfer. According to one embodiment of the present invention, as shown in FIGS. 2A-3B, Sun Microsystems, Mountain View, Calif.
osystems, Inc.) (Solaris)
v. 5.4 A first computer system running under the operating system communicates with a second computer system running either under the Solaris operating system or under a different operating system via the Internet I do. Each computer system uses a number of modules to transfer data calls to and from other computer systems. In order to provide the service of a service call, the data transfer system supports four types of operations: call start (CI), call update (CU), and state update (S).
U), and call closure (CC). The call invoke operation services the first computer system via a call management tool such as the SOTOOL v. 2.4.4e program available from Sun Microsystems, Inc. of Mountain View, California. You need to enter an order. The service order is then assigned to a business partner. This is reflected on the SOTOOL module 203 by entering the partner code value in the assignment field. Once the service order information has been entered into the system via SOTOOL 203, the data is stored in CMSDB
Stored in the database 201. If the information stored in the CMSDB database 201 is incomplete, the status field is used to indicate that further action is required before the service call data can be sent to the business partner.

The call update operation is similar to the call invoke operation, except that it assumes that the data for the service call has already been sent via the call invoke operation. As a result, only the data that needs to be changed and needs to be updated in the business partner's database is sent. State update operations, on the other hand, require receiving data from a business partner reporting on the state of the service call. The received data is merged into the CMSDB database 201 to allow further processing by SOTOOL 203 to display the correct status field. Then, the call closing operation requires receiving data from the business partner regarding the final decision of the service call. The information received by the service partner is then passed to SOTOOL 20
CMSDB to allow 3 to correctly handle service call decisions
Merged into the database 201. A call closure operation is expected for each call activation operation.

Using the first computer system as a reference, FIGS. 2A-2B illustrate a second computer system used for call initiation and call update operations.
Outbound processing for transferring data to a computer system. 3A-3B illustrate an inbound process of receiving data from a second computer system to a first computer system for use in a state update and call close operation. FIG. 2A shows the functional components of a data transfer module of a computer system used in the outbound portion of the data transfer operation of FIG. 1B. The data transfer module includes the call management system 20
0, a conversion module 210, an encryption module 220,
It has a sendmail module 230 and an ISO fax module 240. The call management system 200 then proceeds to the CMSDB database 201, SOTOOL module 203, EVIL (Edit Validation I
The module includes an Nterpretive Language module 205, an Extract module 206 for Q, a CI / CU file 207, an Extract server 208, and an Ack-Fax server (Server) 209. The conversion module 220
It has a mapping / translation module 213, an X12.143 file 216, and a data conversion file 219. And the encryption module 2
20 has an encryption / MIME module 224 and a MIME mail file 228. The operation of these modules is described below.

First, a SOTOOL module 20
Call management system 200 using service call 3
Set to. The SOTOOL module 203 provides the computer system user with a CMSDB database 20
1 having a graphical user interface portion for inputting, viewing and updating information stored in the storage device. Sotool (SOT
OOL) module 203 using the CMSDB database 20
The data input to 1 is then stored in the EVIL module 20
Authorized using 5. EVIL module 205 is a CMSD
B is a computer process performed by a computer system that authenticates whether data stored in database 201 is in a valid format for transmission to a business partner specified by a partner code in an assignment field. If the data verification operation is successful, the EVIL module 205 records the data in an extra queue (not shown) to indicate that the data is ready to be sent to the business partner.
Call the Extract module 206 for Q.

Extract server module 208
Then monitors the extraction queue and extracts the data from the CMSDB database 201 if data is present in the queue and stores it in the flat file CI / CU 207 to be serviced by the conversion module 210. The conversion module 210 is a computer process executed by a computer system that converts a flat data file into a predetermined standard format. Sterling software in Dublin, Ohio
The MENTOR v.1.2-7 program available from Software), Inc. is suitable for use in the present invention to implement the conversion module 210. Those skilled in the art will recognize that any suitable conversion program known in the art can be substituted for the MENTOR program. The Mapping / Translation module 213 then converts the flat file CI / C generated by the Extract server module 208.
Read U 207 and convert it to X 12.143 file 216. X 12.143 file 216
Is the American National Standards Insti
file formatted according to the ANSI X12 standard set by (tute). A copy of the converted data is also stored in the data conversion file 219 for use in recovering from a data transmission operation failure. The encryption / MIME module 224 then encrypts the X12.143 file 216 using well-known encryption methods. For example, in the preferred embodiment, the file is a data encryption standard (Data Encryption S
tandard (DES)) method and the key is (R
evest Shamir Adelman (RSA)). The TEMPLAR v.1.4 program, available from Premenos, Corp. of Dublin, Ohio, is a cryptographic module 2
20 is an encryption package suitable for use with the present invention to achieve 20. One skilled in the art will recognize that any suitable encryption program can be used in place of the TEMPLAR program. The encrypted file is
Then, to generate the MIME mail file 228,
T's Multipurpose Internet Mail Extension
ternet Mail Extensions) Packaged using the protocol. The MIME mail file 228 is then sent over the Internet by the send mail module 230. FIG. 2B illustrates the configuration of the file system 250 and the processing performed by the operating computer system described with respect to FIG. 2A. First, the format file (eg, CI.KODAK or CU.KODAK)
Reads from the directory $ SUNSOX # HOME / <partner> / out / formats, where <tner> is the name of the directory assigned to the file for the particular business partner. Those skilled in the art will appreciate that although the UNIX file system is described for clarity, the present invention is not limited to computer systems running under a particular operating system. The UNIX file system is referred to herein as “The UN
IX Programming Environment ", by Brian W. Kernigha
n, Rob Pike (Englewood Cliffs, NJ: Prentice-Hall,
1984). The format file is used to specify what data should be extracted from the CMSDB database 201 to meet the needs of each business partner. The advantage of using a format file is that if the business partner's needs change, only the partner's format file needs to be changed, and the extraction server 208 does not need to be changed. According to the format file
Two flat files containing data extracted from the CMSDB database 201 are stored in ./appl/CI (or.
/ appl / CU) and $ SUNSOX # HOME / outq / CI / app
Temporarily linked to lq (or $ SUNSOX # HOME / outq / CU / applq). $ SUNSOX # HOME / outq / CI / applq (or $ SUNSOX #
HOME / outq / CU / applq)
After the conversion operation is completed, it is deleted and ./appl/CI (or.
A copy at (/ appl / CU) is kept for archival purposes.

Next, the conversion module 210 determines that X 1
2.143 file 216 in directory ./ansi/CI
(Or ./ansi/CU) and write it to a directory
$ SUNSOX # HOME / outq / CI / ansiq (or $ SUNSOX # HOME / outq /
CU / ansiq). Directory $ SUNSOX # HOME / outq / CI / a as well as the extracted data files
The copy in nsiq (or $ SUNSOX # HOME / outq / CU / ansiq) is deleted after the encryption operation is completed and ./ansi/CI
Copies at (or ./ansi/CU) are retained for archival purposes. The encryption module 210 also maintains a log and a backup file. FIG. 3A shows FIG. 1B
2 illustrates functional components of a data transfer module of a computer system used for an inbound portion of the data transfer operation of FIG. The data transfer module includes a send mail module 330, a decryption module 320, a conversion module 310, and a call management system 300. Decryption module 320 then proceeds to MIME mail module 328, decryption / MIME module 324,
And X 12.141, 142 files 316.
The conversion module 310 includes a mapping / conversion module 313, a data conversion file 319, and an SU / CC file 317. Then, the call management system 300
Is merge 306 for Q module, merge log 3
07, merge server 308, and CMSDB database 3
01. The operation of these modules is described below.

First, data packaged in the MIME format is received by the send mail module 330 over the Internet. The send mail module 330 then generates a MIME mail file 328. The decryption / MIME module 324 unpacks, certifies, and decrypts the MIME mail file 328, and sends the X 12.142, 143 file 31
6 is generated. The package unpacking operation involves decoding the MIME encoded data. The attestation operation involves verifying that the data transferred over the Internet 130 has not been compromised. The decryption operation involves decrypting data encrypted using DES and RSA, described with reference to FIG. 2A. Since those skilled in the art are familiar with these techniques, they will not be described further here.

The mapping / conversion module 313 then converts the X 12.142, 143 file 316 into a CMSDB
Convert to a format compatible with the database 301. ANSI X12 version 141 updates status (SU)
Used for operation, ANSI X12 version 142 is used for Call Close (CC) operation. The mapping / conversion module 313 stores the converted data in the SU / CC file 317. A copy of the converted data is also stored in the data conversion file 219 for use in recovering from a failed data conversion operation. The merge module 306 for Q then converts the converted data to the CMSD
B Record the data of the SU / CC file 317 in the merge logic 307 to indicate that it should be merged into the database 301. The merge server 308
The merge logic 307 is monitored, and if data exists in the merge logic 307, the data is merged into the CMSDB database 301.

FIG. 3B illustrates the configuration of the file system 350 and the processing performed by the operating computer system described with respect to FIG. 3A. First, the decryption module 320 converts the MIME mail file 328 received on the Internet and stores the result in the directory $ S
X 12.142, 143 file 31 of UNSOX # HOME / inq
6 is stored. The X12.142,143 file 316 is then copied to the directory ./ansi and temporarily linked to the directory $ SUNSOX # HOME / <partner> / in / ansi. The conversion module module 310 is X1
2. Convert 142, 143 file 316 and store the result of the conversion in directory ./appl and directory
Write to SU / CC file 317 temporarily linked to $ SUNSOX # HOME / <partner> / in / appl. Then, the conversion module 310 updates the merge logic 307. Upon completion of the conversion operation, the directory $ SUNSOX # HOME
X 12.142, 143 file 31 stored in / inq
6 is deleted. Also, the directory $ SUNSOX # HOME / <pa
rtner> / in / ansi and $ SUNSOX # HOME / <partner> / in / app
The temporary link to l is also removed, but the directory ./an
The files stored in si and ./appl are saved for recording purposes.

The operation of the extraction server 308 (FIG. 2A) is summarized in FIG. First, the stage (stage) 410
Determines if there is an entry in the extraction log, and if so, the operation proceeds to stage 420; otherwise, the operation ends. Stage 420 then determines whether the data was extracted as part of the call update operation, and if so, the required data for the call update operation for the business partner identified by the extract log is stage 440. Otherwise (i.e., if the data was extracted as part of the call activation operation), the data required for the call activation operation is extracted from the database at stage 430. The extracted data log is then updated at stage 450. One skilled in the art will recognize that any method known in the art can be used to update the extraction log. For example, in one embodiment, the data is simply removed from the log; in other embodiments, a value is entered into a particular field of the log to indicate that the data has been extracted. The database is then updated at stage 460 to indicate that the data has been extracted.

Those skilled in the art will appreciate that the extraction server 208 (FIG. 2A) can be implemented by any suitable computer processing running on a computer system and performing the operations of FIG. . For example, in one embodiment of the present invention, the extraction server 208 is implemented by a daemon that is automatically executed by the Solaris operating system. Since daemon programs are well known to those skilled in the art, no further description is provided here. To ensure continuous execution of the extraction server 208, the cloning process periodically checks to ensure that the daemon implementing the extraction server 208 is running and restarts the daemon if necessary. . The operation of the merge server 308 (FIG. 3A)
It is summarized in FIG. First, stage 510 determines if an entry exists in merge logic 307 (FIG. 3A) and, if so, stores it in a database that should be updated with data received from the second computer system. The data to be retrieved is retrieved from the database at stage 520; otherwise, the operation ends. At stage 530, the data retrieved from the database is updated with the data retrieved from the second computer system, and the updated data is stored back in the database. At stage 540, merge logic 307 is updated to indicate that the data has been merged into the database. Stage 510
540 are then repeated until all of the merge logic 307 entries have been processed.

Those skilled in the art will appreciate that the merge server 308 (FIG. 3A) can be implemented by any suitable computer processing running on a computer system and performing the operations of FIG. . For example, in one embodiment of the present invention, the merge server 308
Implemented by a daemon that is automatically executed by the Solaris operating system. Merge server 3
To ensure continuous execution of 08, the cloning process periodically checks to ensure that the daemon implementing the merge server 308 is running and, if necessary, restart it. Ack-Fax server 209 (
The operation of FIG. 2A) is summarized in FIG. First, stage 600 determines whether an entry exists in the cent data log, and if so, the cent data log is updated at stage 610; otherwise, the operation ends. Stage 620 then determines whether any of the entries in the cent data log were not acknowledged by the second computer system, and if not, operation proceeds to stage 630.
Proceed to; otherwise, the operation ends. Stage 630 then determines whether a predetermined period has elapsed since the data corresponding to the entry was sent to the second computer system, and if so, the operation proceeds to stage 64.
0; otherwise, the operation ends. Then, in stage 640, the data is automatically transmitted to the business partner via facsimile. And stage 6
At 50, the system administrator of the second computer system is paged to inform that the data transfer has been retransmitted via facsimile.

Those skilled in the art will recognize that the Ack-Fax server 209 (FIG. 2A) will execute any suitable computer processing running on the computer system and performing the operations of FIG.
Can be realized.
For example, in one embodiment of the present invention, the Ack-Fax server 209
Is implemented by a daemon that is automatically executed by the Solaris operating system. In order to ensure continuous execution of the Ack-Fax server 209, the cloning process
Check periodically to ensure that the daemon implementing the Ack-Fax server 209 is running and restart the daemon if necessary. Further, any suitable program known in the art can be used to send data to a business partner via facsimile. For example, in one embodiment of the present invention, the ISOFAX available from Bristol Group, Ltd. of Larkspur, California.
The program is used to send data to business partners.

Solaris and SOTOOL are registered trademarks of Sun Microsystems, Inc. of Mountain View, CA; MENTOR is a registered trademark of Sterling Software, Inc. of Concordia, CA; TEMPLAR is a registered trademark of Dublin, Ohio. Premenos, Cor
is a registered trademark and ISOFAX is a trademark of Bristol Group of Larkspur, California,
Ltd. is a registered trademark. The embodiments described above illustrate, but do not limit, the invention. In particular, the invention is not limited by any particular formatting and encryption techniques. For example, one embodiment uses a format other than ANISI X12 to format data extracted from a database and uses DES and
Use an encryption standard other than RSA. Further, the invention is not limited to any number of computers connected to the global network. Other embodiments and modifications are within the scope of the invention, as defined by the claims.

[0028]

The method of the present invention is a method for performing reliable data transfer on a global computer network, wherein data stored on a first computer system connected to the global computer network is transferred to a global computer network. Transmitting to a second computer system connected to the network; receiving data from the second computer system to the first computer system to send an acknowledgment signal; Monitoring the acknowledgment signal received by the first computer system to determine if it was received by the system; and facsimile by determining that no data was received by the second computer system. Because comprising the step of transmitting the data automatically through, it is possible to perform the data transfer operation reliability lies in the global computer network.

[0029] The computer system of the present invention is a computer system for performing reliable data transfer over a global computer network, the system comprising a first and a second programmed computer connected to the global computer network. Wherein the first computer transmits data stored on the first computer system connected to the global computer network to a second computer system connected to the global computer network;
Monitoring the acknowledgment signal received by the first computer system to determine whether data was received by the second computer system; and determining that the data was not received by the second computer system , A command for automatically transmitting data via facsimile is provided, so that a reliable data transfer operation can be performed in a global computer network.

[0030] The computer readable medium of the present invention is a computer readable medium storing a computer program, and the program reads data stored in a first computer system connected to a global computer network. Transmitting to a second computer system connected to the network; monitoring an acknowledgment signal received by the first computer system to determine whether the data has been received by the second computer system; Reliable data in a global computer network with instructions to automatically transmit data via facsimile upon a determination that it was not received by a second computer system It is possible to perform the feeding operation.

The computer readable medium of the present invention is a computer readable medium storing a computer program, the program receiving data on a second computer system connected to a global computer network; Instructions for receiving data from the second computer system to the first computer system and sending an acknowledgment signal to the first computer system so as to perform a reliable data transfer operation in the global computer network. it can.

[Brief description of the drawings]

FIG. 1A is a block diagram of a data transfer system according to one embodiment of the present invention.

FIG. 1B is a block diagram of a data transfer module of the sending computer 110 or the receiving computer 120 of FIG. 1A.

FIG. 2A illustrates extracting data from a database of a call management system of a first computer system, converting it to a predetermined format, encrypting the formatted data, and encrypting the data over a network to a second computer system. FIG. 7 is a block diagram of a process for transmitting the data.

FIG. 2B is a functional diagram showing a relationship between processing executed by the first computer system in FIG. 2A and stored files.

FIG. 3A receives data transmitted over the Internet by the first computer system of FIGS. 2A-2B at a second computer system, decrypts the encrypted data, and executes the decrypted data at a second computer FIG. 9 is a block diagram of a process for converting to a format compatible with the call management system being performed and storing the reformatted data in a database of a second computer system.

FIG. 3B is a functional diagram showing a relationship between processing executed by the second computer system of FIG. 3A and stored files.

FIG. 4 is a flowchart showing the operation of the Extract server of FIG. 2A.

FIG. 5 is a flowchart showing the operation of the Merge server 308 in FIG. 3A.

FIG. 6 is a flowchart showing the operation of the Ack-Fax server 209 of FIG. 2A.

[Explanation of symbols]

 100 data transfer module 105 call management system 115 extraction module 125 outbound conversion module 130 internet 135 encryption module 145 decryption module 155 inbound conversion module 165 merge module

────────────────────────────────────────────────── (5) Continuation of the front page (51) Int.Cl. ⁶ Identification code FI H04N 1/00 (71) Applicant 591064003 901 SAN ANTONIO ROAD PALO ALTO, CA 94303, US A. (72) Inventor Deepak Allure USA 95035 Milpitas Dixon Landing Road 231 Apartment 230 (72) Inventor Marts Janson United States of America 94061 Redwood Carson Street 2434 (72) Inventor Virginia Sea Hide United States of America California State 95051 Santa Clara Esteira de Live 2716

Claims (9)

[Claims] 1. A method for performing reliable data transfer on a global computer network, comprising: storing data stored on a first computer system connected to the global computer network connected to the global computer network; Transmitting the data to the second computer system by receiving the data from the second computer system.
Sending an acknowledgment signal from the computer system to the first computer system; and an acknowledgment signal received by the first computer system to determine whether the data has been received by the second computer system. Monitoring the data; and automatically transmitting the data via facsimile upon a determination that the data was not received by the second computer system. 2. The method of claim 1, further comprising automatically transmitting a paging signal upon a determination that the data was not received by the second computer system. 3. The method of claim 1, wherein the data receipt is acknowledged in real time. 4. A computer system for performing reliable data transfer over a global computer network, said system comprising first and second programmed computers connected to a global computer network. A first computer configured to transfer data stored in a first computer system connected to the global computer network to a second computer connected to the global computer network;
Monitoring an acknowledgment signal received by the first computer system to determine whether the data has been received by the second computer system; and wherein the data has been received by the second computer system. Computer system comprising instructions for automatically transmitting said data via facsimile upon a determination that it was not received by said computer system. 5. The second programmed computer receives the data at the second computer system connected to the global computer network; and receives the data at the second computer system. The computer system of claim 4, further comprising instructions for receiving an acknowledgment signal from a second computer system to the first computer system. 6. The first programmed computer system further comprises instructions for automatically transmitting a paging signal upon a determination that the data was not received by the second computer system. The computer system according to claim 4, wherein: 7. A computer-readable medium storing a computer program, the program comprising: data stored in a first computer system connected to the global computer network connected to the global computer network. Second
Monitoring an acknowledgment signal received by the first computer system to determine whether the data has been received by the second computer system; and wherein the data has been received by the second computer system. A computer readable medium comprising instructions for automatically transmitting said data via facsimile upon a determination that the data has not been received by the computer system. 8. The computer of claim 7, further comprising instructions for automatically transmitting a paging signal upon a determination that the data was not received by the second computer system. Readable media. 9. A computer readable medium storing a computer program, said program receiving said data on said second computer system connected to said global computer network; and said second computer A computer-readable medium comprising instructions for receiving the data from the second computer system to the first computer system by receiving the data and sending an acknowledgment signal.